Enumerations
Enumerations
An enumeration defines a common type for a group of related values and enables you to work with those values in a type-safe way within your code.
If you are familiar with C, you will know that C enumerations assign related names to a set of integer values. Enumerations in Swift are much more flexible, and don’t have to provide a value for each case of the enumeration. If a value (known as a raw value) is provided for each enumeration case, the value can be a string, a character, or a value of any integer or floating-point type.
Alternatively, enumeration cases can specify associated values of any type to be stored along with each different case value, much as unions or variants do in other languages. You can define a common set of related cases as part of one enumeration, each of which has a different set of values of appropriate types associated with it.
Enumerations in Swift are first-class types in their own right. They adopt many features traditionally supported only by classes, such as computed properties to provide additional information about the enumeration’s current value, and instance methods to provide functionality related to the values the enumeration represents. Enumerations can also define initializers to provide an initial case value; can be extended to expand their functionality beyond their original implementation; and can conform to protocols to provide standard functionality.
For more about these capabilities, see Properties, Methods, Initialization, Extensions, and Protocols.
Enumeration Syntax
You introduce enumerations with the enum
keyword and place their entire definition within a pair of braces:
enum SomeEnumeration {
// enumeration definition goes here
}
Here’s an example for the four main points of a compass:
enum CompassPoint {
case north
case south
case east
case west
}
The values defined in an enumeration (such as north
, south
, east
, and west
) are its enumeration cases. You use the case
keyword to introduce new enumeration cases.
Note
Swift enumeration cases don’t have an integer value set by default, unlike languages like C and Objective-C. In the CompassPoint
example above, north
, south
, east
and west
don’t implicitly equal 0
, 1
, 2
and 3
. Instead, the different enumeration cases are values in their own right, with an explicitly defined type of CompassPoint
.
Multiple cases can appear on a single line, separated by commas:
enum Planet {
case mercury, venus, earth, mars, jupiter, saturn, uranus, neptune
}
Each enumeration definition defines a new type. Like other types in Swift, their names (such as CompassPoint
and Planet
) start with a capital letter. Give enumeration types singular rather than plural names, so that they read as self-evident:
var directionToHead = CompassPoint.west
The type of directionToHead
is inferred when it’s initialized with one of the possible values of CompassPoint
. Once directionToHead
is declared as a CompassPoint
, you can set it to a different CompassPoint
value using a shorter dot syntax:
directionToHead = .east
The type of directionToHead
is already known, and so you can drop the type when setting its value. This makes for highly readable code when working with explicitly typed enumeration values.
Matching Enumeration Values with a Switch Statement
You can match individual enumeration values with a switch
statement:
directionToHead = .south
switch directionToHead {
case .north:
print("Lots of planets have a north")
case .south:
print("Watch out for penguins")
case .east:
print("Where the sun rises")
case .west:
print("Where the skies are blue")
}
// Prints "Watch out for penguins"
You can read this code as:
“Consider the value of directionToHead
. In the case where it equals .north
, print "Lots of planets have a north"
. In the case where it equals .south
, print "Watch out for penguins"
.”
…and so on.
As described in Control Flow, a switch
statement must be exhaustive when considering an enumeration’s cases. If the case
for .west
is omitted, this code doesn’t compile, because it doesn’t consider the complete list of CompassPoint
cases. Requiring exhaustiveness ensures that enumeration cases aren’t accidentally omitted.
When it isn’t appropriate to provide a case
for every enumeration case, you can provide a default
case to cover any cases that aren’t addressed explicitly:
let somePlanet = Planet.earth
switch somePlanet {
case .earth:
print("Mostly harmless")
default:
print("Not a safe place for humans")
}
// Prints "Mostly harmless"
Iterating over Enumeration Cases
For some enumerations, it’s useful to have a collection of all of that enumeration’s cases. You enable this by writing : CaseIterable
after the enumeration’s name. Swift exposes a collection of all the cases as an allCases
property of the enumeration type. Here’s an example:
enum Beverage: CaseIterable {
case coffee, tea, juice
}
let numberOfChoices = Beverage.allCases.count
print("\(numberOfChoices) beverages available")
// Prints "3 beverages available"
In the example above, you write Beverage.allCases
to access a collection that contains all of the cases of the Beverage
enumeration. You can use allCases
like any other collection—the collection’s elements are instances of the enumeration type, so in this case they’re Beverage
values. The example above counts how many cases there are, and the example below uses a for
-in
loop to iterate over all the cases.
for beverage in Beverage.allCases {
print(beverage)
}
// coffee
// tea
// juice
The syntax used in the examples above marks the enumeration as conforming to the CaseIterable [https://developer.apple.com/documentation/swift/caseiterable\] protocol. For information about protocols, see Protocols.
Associated Values
The examples in the previous section show how the cases of an enumeration are a defined (and typed) value in their own right. You can set a constant or variable to Planet.earth
, and check for this value later. However, it’s sometimes useful to be able to store values of other types alongside these case values. This additional information is called an associated value, and it varies each time you use that case as a value in your code.
You can define Swift enumerations to store associated values of any given type, and the value types can be different for each case of the enumeration if needed. Enumerations similar to these are known as discriminated unions, tagged unions, or variants in other programming languages.
For example, suppose an inventory tracking system needs to track products by two different types of barcode. Some products are labeled with 1D barcodes in UPC format, which uses the numbers 0
to 9
. Each barcode has a number system digit, followed by five manufacturer code digits and five product code digits. These are followed by a check digit to verify that the code has been scanned correctly:
Other products are labeled with 2D barcodes in QR code format, which can use any ISO 8859-1 character and can encode a string up to 2,953 characters long:
It’s convenient for an inventory tracking system to store UPC barcodes as a tuple of four integers, and QR code barcodes as a string of any length.
In Swift, an enumeration to define product barcodes of either type might look like this:
enum Barcode {
case upc(Int, Int, Int, Int)
case qrCode(String)
}
This can be read as:
“Define an enumeration type called Barcode
, which can take either a value of upc
with an associated value of type (Int
, Int
, Int
, Int
), or a value of qrCode
with an associated value of type String
.”
This definition doesn’t provide any actual Int
or String
values—it just defines the type of associated values that Barcode
constants and variables can store when they’re equal to Barcode.upc
or Barcode.qrCode
.
You can then create new barcodes using either type:
var productBarcode = Barcode.upc(8, 85909, 51226, 3)
This example creates a new variable called productBarcode
and assigns it a value of Barcode.upc
with an associated tuple value of (8, 85909, 51226, 3)
.
You can assign the same product a different type of barcode:
productBarcode = .qrCode("ABCDEFGHIJKLMNOP")
At this point, the original Barcode.upc
and its integer values are replaced by the new Barcode.qrCode
and its string value. Constants and variables of type Barcode
can store either a .upc
or a .qrCode
(together with their associated values), but they can store only one of them at any given time.
You can check the different barcode types using a switch statement, similar to the example in Matching Enumeration Values with a Switch Statement. This time, however, the associated values are extracted as part of the switch statement. You extract each associated value as a constant (with the let
prefix) or a variable (with the var
prefix) for use within the switch
case’s body:
switch productBarcode {
case .upc(let numberSystem, let manufacturer, let product, let check):
print("UPC: \(numberSystem), \(manufacturer), \(product), \(check).")
case .qrCode(let productCode):
print("QR code: \(productCode).")
}
// Prints "QR code: ABCDEFGHIJKLMNOP."
If all of the associated values for an enumeration case are extracted as constants, or if all are extracted as variables, you can place a single var
or let
annotation before the case name, for brevity:
switch productBarcode {
case let .upc(numberSystem, manufacturer, product, check):
print("UPC : \(numberSystem), \(manufacturer), \(product), \(check).")
case let .qrCode(productCode):
print("QR code: \(productCode).")
}
// Prints "QR code: ABCDEFGHIJKLMNOP."
Raw Values
The barcode example in Associated Values shows how cases of an enumeration can declare that they store associated values of different types. As an alternative to associated values, enumeration cases can come prepopulated with default values (called raw values), which are all of the same type.
Here’s an example that stores raw ASCII values alongside named enumeration cases:
enum ASCIIControlCharacter: Character {
case tab = "\t"
case lineFeed = "\n"
case carriageReturn = "\r"
}
Here, the raw values for an enumeration called ASCIIControlCharacter
are defined to be of type Character
, and are set to some of the more common ASCII control characters. Character
values are described in Strings and Characters.
Raw values can be strings, characters, or any of the integer or floating-point number types. Each raw value must be unique within its enumeration declaration.
Note
Raw values are not the same as associated values. Raw values are set to prepopulated values when you first define the enumeration in your code, like the three ASCII codes above. The raw value for a particular enumeration case is always the same. Associated values are set when you create a new constant or variable based on one of the enumeration’s cases, and can be different each time you do so.
Implicitly Assigned Raw Values
When you’re working with enumerations that store integer or string raw values, you don’t have to explicitly assign a raw value for each case. When you don’t, Swift automatically assigns the values for you.
For example, when integers are used for raw values, the implicit value for each case is one more than the previous case. If the first case doesn’t have a value set, its value is 0
.
The enumeration below is a refinement of the earlier Planet
enumeration, with integer raw values to represent each planet’s order from the sun:
enum Planet: Int {
case mercury = 1, venus, earth, mars, jupiter, saturn, uranus, neptune
}
In the example above, Planet.mercury
has an explicit raw value of 1
, Planet.venus
has an implicit raw value of 2
, and so on.
When strings are used for raw values, the implicit value for each case is the text of that case’s name.
The enumeration below is a refinement of the earlier CompassPoint
enumeration, with string raw values to represent each direction’s name:
enum CompassPoint: String {
case north, south, east, west
}
In the example above, CompassPoint.south
has an implicit raw value of "south"
, and so on.
You access the raw value of an enumeration case with its rawValue
property:
let earthsOrder = Planet.earth.rawValue
// earthsOrder is 3
let sunsetDirection = CompassPoint.west.rawValue
// sunsetDirection is "west"
Initializing from a Raw Value
If you define an enumeration with a raw-value type, the enumeration automatically receives an initializer that takes a value of the raw value’s type (as a parameter called rawValue
) and returns either an enumeration case or nil
. You can use this initializer to try to create a new instance of the enumeration.
This example identifies Uranus from its raw value of 7
:
let possiblePlanet = Planet(rawValue: 7)
// possiblePlanet is of type Planet? and equals Planet.uranus
Not all possible Int
values will find a matching planet, however. Because of this, the raw value initializer always returns an optional enumeration case. In the example above, possiblePlanet
is of type Planet?
, or “optional Planet
.”
Note
The raw value initializer is a failable initializer, because not every raw value will return an enumeration case. For more information, see Failable Initializers.
If you try to find a planet with a position of 11
, the optional Planet
value returned by the raw value initializer will be nil
:
let positionToFind = 11
if let somePlanet = Planet(rawValue: positionToFind) {
switch somePlanet {
case .earth:
print("Mostly harmless")
default:
print("Not a safe place for humans")
}
} else {
print("There isn't a planet at position \(positionToFind)")
}
// Prints "There isn't a planet at position 11"
This example uses optional binding to try to access a planet with a raw value of 11
. The statement if let somePlanet = Planet(rawValue: 11)
creates an optional Planet
, and sets somePlanet
to the value of that optional Planet
if it can be retrieved. In this case, it isn’t possible to retrieve a planet with a position of 11
, and so the else
branch is executed instead.
Recursive Enumerations
A recursive enumeration is an enumeration that has another instance of the enumeration as the associated value for one or more of the enumeration cases. You indicate that an enumeration case is recursive by writing indirect
before it, which tells the compiler to insert the necessary layer of indirection.
For example, here is an enumeration that stores simple arithmetic expressions:
enum ArithmeticExpression {
case number(Int)
indirect case addition(ArithmeticExpression, ArithmeticExpression)
indirect case multiplication(ArithmeticExpression, ArithmeticExpression)
}
You can also write indirect
before the beginning of the enumeration to enable indirection for all of the enumeration’s cases that have an associated value:
indirect enum ArithmeticExpression {
case number(Int)
case addition(ArithmeticExpression, ArithmeticExpression)
case multiplication(ArithmeticExpression, ArithmeticExpression)
}
This enumeration can store three kinds of arithmetic expressions: a plain number, the addition of two expressions, and the multiplication of two expressions. The addition
and multiplication
cases have associated values that are also arithmetic expressions—these associated values make it possible to nest expressions. For example, the expression (5 + 4) * 2
has a number on the right-hand side of the multiplication and another expression on the left-hand side of the multiplication. Because the data is nested, the enumeration used to store the data also needs to support nesting—this means the enumeration needs to be recursive. The code below shows the ArithmeticExpression
recursive enumeration being created for (5 + 4) * 2
:
let five = ArithmeticExpression.number(5)
let four = ArithmeticExpression.number(4)
let sum = ArithmeticExpression.addition(five, four)
let product = ArithmeticExpression.multiplication(sum, ArithmeticExpression.number(2))
A recursive function is a straightforward way to work with data that has a recursive structure. For example, here’s a function that evaluates an arithmetic expression:
func evaluate(_ expression: ArithmeticExpression) -> Int {
switch expression {
case let .number(value):
return value
case let .addition(left, right):
return evaluate(left) + evaluate(right)
case let .multiplication(left, right):
return evaluate(left) * evaluate(right)
}
}
print(evaluate(product))
// Prints "18"
This function evaluates a plain number by simply returning the associated value. It evaluates an addition or multiplication by evaluating the expression on the left-hand side, evaluating the expression on the right-hand side, and then adding them or multiplying them.